Method and apparatus for transmitting and receiving control information to randomize inter-cell interference in a mobile communication system

ABSTRACT

A method and apparatus for transmitting and receiving control information in an SC-FDMA system are provided. Different orthogonal codes are generated for different slots each including a plurality of SC-FDMA symbols in a subframe. A control channel signal is generated by multiplying control symbols carrying control information by a sequence allocated for CDM of the control information. The control channel signal is multiplied by chips of the orthogonal codes on an SC-FDMA symbol basis and transmitted in the SC-FDMA symbols.

PRIORITY

This application claims priority under 35 U.S.C. §119(a) to a Korean Patent Application filed in the Korean Intellectual Property Office on Jan. 5, 2007 and assigned Serial No. 2007-1329, a Korean Patent Application filed in the Korean Intellectual Property Office on Jan. 10, 2007 and assigned Serial No. 2007-3039, and a Korean Patent Application filed in the Korean Intellectual Property Office on May 10, 2007 and assigned Serial No. 2007-45577, the disclosures of which are incorporated herein by reference.

BACKGROUND OF THE INVENTION

1. Field of the Invention

The present invention relates generally to a mobile communication system, and more particularly, to a method and apparatus for transmitting and receiving control information to randomize inter-cell interference caused by UpLink (UL) transmission in a future-generation multi-cell mobile communication system.

2. Description of the Related Art

In the field of mobile communication technologies, Orthogonal Frequency Division Multiple Access (OFDMA), or Single Carrier-Frequency Division Multiple Access (SC-FDMA), has recently been studied for high-speed transmission on radio channels. The asynchronous cellular mobile communication standardization organization, 3^(rd) Generation Partnership Project (3GPP) is working on a future-generation mobile communication system, Long Term Evolution (LTE), in relation to the multiple access scheme.

The LTE system uses a different Transport Format (TP) for UL control information depending on data transmission or non-data transmission. When data and control information are transmitted simultaneously on the UL, they are multiplexed by Time Division Multiplexing (TDM). If only control information is transmitted, a particular frequency band is allocated for the control information.

FIG. 1 is a diagram illustrating a transmission mechanism when only control information is transmitted on the UL in a conventional LTE system. The horizontal axis represents time and the vertical axis represents frequency. One subframe 102 is defined in time and a Transmission (TX) bandwidth 120 is defined in frequency.

Referring to FIG. 1, a basic UL time transmission unit, the subframe 102, is 1 ms long and includes two slots 104 and 106, each 0.5 ms long. Each slot 104 or 106 is comprised of a plurality of Long Blocks (LBs) 108 (or long SC-FDMA symbols) and Short Blocks (SBs) 110 (or short SC-FDMA symbols). In the illustrated case of FIG. 1, a slot is configured so as to have six LBs 108 and two SBs 110.

A minimum frequency transmission unit is a frequency tone of an LB, and a basic resource allocation unit is a Resource Unit (RU). RUs 112 and 114 each have a plurality of frequency tones. Herein, 12 frequency tones form one RU, by way of example. Frequency diversity can also be achieved by forming an RU with scattered frequency tones, instead of successive frequency tones.

Since the LBs 108 and the SBs 110 have the same sampling rate, the SBs 110 have a frequency tone size twice that of the LBs 108. The number of frequency tones allocated to one RU in the SBs 110 is half that of frequency tones allocated to one RU in the LBs 108. In the illustrated case of FIG. 1, the LBs 108 carry control information, while the SBs 110 carry a pilot signal (or a Reference Signal (RS)). The pilot signal is a predetermined sequence by which a receiver performs channel estimation for coherent demodulation.

If only control information is transmitted on the UL, it is transmitted in a predetermined frequency band in the LTE system. In FIG. 1, the frequency band is at least one of the RUs 112 and 114 at either side of the TX bandwidth 120.

In general, the frequency band carrying control information is defined in units of RUs. When a plurality of RUs is required, successive RUs are used to satisfy a single carrier property. To increase frequency diversity for one subframe, frequency hopping can occur, herein on a slot basis.

In FIG. 1, first control information (Control #1) is transmitted in the RU 112 in a first slot 104 and in the RU 114 in a second slot 106 by frequency hopping. Meanwhile, second control information (Control #2) is transmitted in the RU 114 in the first slot 104 and in the RU 112 in the second slot 106 by frequency hopping.

The control information is, for example, feedback information indicating successful or failed reception of DownLink (DL) data, ACKnowledgment/Negative ACKnowledgment (ACK/NACK) that is generally 1 bit. It is repeated in a plurality of LBs in order to increase reception performance and expand cell coverage. When 1-bit control information is transmitted from different users, Code Division Multiplexing (CDM) can be considered for multiplexing the 1-bit control information. CDM is characterized by robustness against interference, compared to Frequency Division Multiplexing (FDM).

A Zadoff-Chu (ZC) sequence is discussed as a code sequence for CDM-multiplexing of control information. Due to its constant envelopment in time and frequency, the ZC sequence offers good Peak-to-Average Power Ratio (PAPR) characteristics and excellent channel estimation performance in frequency. PAPR is the most significant consideration for UL transmission. A higher PAPR leads to a smaller cell coverage, thereby increasing a signal power requirement for a User Equipment (UE). Therefore, efforts should first be expanded toward PAPR reduction in UL transmission.

A ZC sequence with good PAPR characteristics has a circular auto-correlation value of 0 with respect to a non-zero shift. Equation (1) below describes the ZC sequence mathematically.

$\begin{matrix} {{g_{p}(n)} = \left\{ \begin{matrix} {^{{- j}\frac{2\pi}{N}\frac{{pn}^{2}}{2}},} & {{when}\mspace{14mu} N\mspace{14mu} {is}\mspace{14mu} {even}} \\ {^{{- j}\frac{2\pi}{N}\frac{{pn}{({n + 1})}}{2}},} & {{when}\mspace{14mu} N\mspace{14mu} {is}\mspace{14mu} {odd}} \end{matrix} \right.} & (1) \end{matrix}$

where N denotes the length of the ZC sequence, p denotes the index of the ZC sequence, and n denotes the index of a sample of the ZC sequence (n=0, . . . , N−1). Because p and N should be relatively prime, the number of sequence indexes p varies with the sequence length N. Hence for N=6, p=1,5, two ZC sequences are generated. If N is a prime number, N−1 sequences are generated.

Two ZC sequences with different p values generated by equation (1) have a complex cross-correlation, of which the absolute value is 1/°{square root over (N)} and the phase varies with p.

Control information from a user is distinguished from control information from other users by a ZC sequence and is described in greater detail by way of example.

Within the same cell, 1-bit control information from different UEs is identified by time-domain cyclic shift values of a ZC sequence. The cyclic shift values are UE-specific to satisfy the condition that they are larger than the maximum transmission delay of a radio transmission path, thus ensuring mutual orthogonality among the UEs. Therefore, the number of UEs that can be accommodated for multiple access depends on the length of the ZC sequence and the cyclic shift values. For example, if the ZC sequence is 12 samples long and a minimum cyclic shift value ensuring orthogonality between ZC sequences is 2 samples, multiple access is available to six UEs (=12/2).

FIG. 2 illustrates a transmission mechanism in which control information from UEs is CDM-multiplexed.

Referring to FIG. 2, first and second UEs 204 and 206 (UE #1 and UE #2) use the same ZC sequence, ZC #1 in LBs, in a cell 202 (Cell A), and cyclically shift ZC #1 by 0 208 and A 210 respectively, for user identification. In the illustrated case of FIG. 2, to expand cell coverage, UE #1 and UE #2 each generate a control channel signal by repeating the modulation symbol of intended 1-bit UL control information six times, i.e. in six LBs and multiplying the repeated symbols by the cyclically shifted ZC sequence, ZC #1 in each LB. These control channel signals are kept orthogonal without interference between UE #1 and UE #2 in view of the circular auto-correlation property of the ZC sequence. Δ210 is set to be larger than the maximum transmission delay of the radio transmission path. Two SBs in each slot carry pilots for coherent demodulation of the control information. For illustrative purposes, only one slot of the control information is shown in FIG. 2.

In a cell 220 (Cell B), third and fourth UEs 222 and 224 (UE #3 and UE #4) use the same ZC sequence, ZC #2 in the LBs, and cyclically shift ZC #2 by 0 226 and A 228 respectively, for user identification. In view of the circular auto-correlation property of the ZC sequence, control channel signals from UE #3 and UE #4 are kept orthogonal without interference between them.

This control information transmission scheme, however, causes interference between different cells as control channel signals from UEs in the cells use different ZC sequences. In FIG. 2, UE #1 and UE #2 of Cell A use different ZC sequences from those of UE #3 and UE #4 of Cell B. The cross-correlation property of the ZC sequences cause interference among the UEs in proportion to the cross-correlation between the ZC sequences. Accordingly, there exists a need for a method for reducing inter-cell interference caused by control information transmission as described above.

SUMMARY OF THE INVENTION

The present invention has been made to address at least the above problems and/or disadvantages and to provide at least the advantages described below. Accordingly, an aspect of the present invention provides a method and apparatus for reducing inter-cell interference when control information from different users is multiplexed in a multi-cell environment.

Another aspect of the present invention provides a method and apparatus for further randomizing inter-cell interference by applying a cell-specific or UE-specific random sequence to control information in a subframe.

A further aspect of the present invention provides a method and apparatus for notifying a UE of a random sequence applied to control information in a subframe by Layer 1/Layer 2 (L1/L2) signaling.

An additional aspect of the present invention provides a method and apparatus for effectively receiving control information in a subframe without inter-cell interference.

According to one aspect of the present invention, a method for transmitting control information in an SC-FDMA system is provided. Different orthogonal codes are generated for different slots each including a plurality of SC-FDMA symbols in a subframe. A control channel signal is generated by multiplying control symbols carrying control information by a sequence allocated for CDM of the control information. The control channel signal is multiplied by chips of the orthogonal codes on an SC-FDMA symbol basis and transmitted in the SC-FDMA symbols.

According to another aspect of the present invention, a method for receiving control information in an SC-FDMA system is provided. Different orthogonal codes are generated for different slots each including a plurality of SC-FDMA symbols in a subframe. A received control channel signal is multiplied by a conjugate sequence of a sequence allocated for CDM of the control information. The control information is acquired by multiplying the multiplied control channel signal by chips of the orthogonal codes on an SC-FDMA symbol basis.

According to a further aspect of the present invention, an apparatus for transmitting control information in an SC-FDMA system is provided. A control channel signal generator generates a control channel signal by multiplying control symbols including control information by a sequence allocated for CDM of the control information. A transmitter generates different orthogonal codes for different slots each including a plurality of SC-FDMA symbols in a subframe, multiplies the control channel signal by chips of the orthogonal codes on an SC-FDMA symbol basis, and transmits the multiplied control channel signal in the SC-FDMA symbols.

According to an additional aspect of the present invention, an apparatus for receiving control information in an SC-FDMA system is provided. A receiver receives a control channel signal including control information. A control channel signal receiver multiplies the control channel signal by a conjugate sequence of a sequence allocated for CDM of the control information and acquires the control information by multiplying the multiplied control channel signal by chips of different orthogonal codes used for different slots each including a plurality of SC-FDMA symbols in a subframe, on an SC-FDMA symbol basis.

BRIEF DESCRIPTION OF THE DRAWINGS

The above and other aspects, features and advantages of certain exemplary embodiments of the present invention will be more apparent from the following detailed description when taken in conjunction with the accompanying drawings, in which:

FIG. 1 is a diagram illustrating a transmission mechanism for control information in a conventional LTE system;

FIG. 2 illustrates a transmission mechanism in which control information from UEs is CDM-multiplexed;

FIG. 3 is a flowchart illustrating operation for transmitting control information in a UE according to an embodiment of the present invention;

FIG. 4 is a flowchart illustrating operation for receiving control information in a Node B according to an embodiment of the present invention;

FIG. 5 is a diagram illustrating a transmission mechanism for control information according to an embodiment of the present invention;

FIGS. 6A and 6B are block diagrams illustrating a transmitter in the UE according to an embodiment of the present invention;

FIGS. 7A and 7B are block diagrams illustrating a receiver in the Node B according to an embodiment of the present invention;

FIG. 8 is a diagram illustrating a transmission mechanism for control information according to an embodiment of the present invention;

FIG. 9 is a diagram illustrating another transmission mechanism for control information according to an embodiment of the present invention;

FIGS. 10A and 10B are block diagrams illustrating a transmitter in the MS according to an embodiment of the present invention;

FIGS. 11A and 11B are block diagrams illustrating a receiver in the Node B according to an embodiment of the present invention;

FIGS. 12A and 12B are diagrams illustrating a transmission mechanism for control information according to an embodiment of the present invention; and

FIG. 13 is a diagram illustrating another transmission mechanism for control information according to an embodiment of the present invention.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS

Preferred embodiments of the present invention are described in detail with reference to the accompanying drawings. It should be noted that similar components are designated by similar reference numerals although they are illustrated in different drawings. Detailed descriptions of constructions or processes known in the art may be omitted to avoid obscuring the present invention.

Embodiments of the present invention provide transmission and reception operations of a UE and a Node B in the case where UL control information from a plurality of UEs are multiplexed over a predetermined frequency area of a system frequency band.

Embodiments of the present invention will be described in the context of CDM transmission of control information from a plurality of UEs in an SC-FDMA cellular communication system. Embodiments of the present invention are also applicable to multiplexing that does not share particular time-frequency resources, for example, FDM or TDM transmission of the control information. CDM can be one of various CDMA schemes including time-domain CDMA and frequency-domain CDM.

For CDM, a ZC sequence is used, although any other code sequence with similar characteristics is also available for use. The control information is 1-bit control information such as ACK/NACK herein, by way of example. However, an inter-cell interference reduction method of the present invention is also applicable to control information with a plurality of bits such as a Channel Quality Indicator (CQI). In this case, each bit of the control information is transmitted in one SC-FDMA symbol. The inter-cell interference reduction method is also applicable to CDM transmission of different types of control information, for example, 1-bit control information and control information with a plurality of bits.

Inter-cell interference occurs when UEs in adjacent cells transmit their control information using different ZC sequences of length N in M SC-FDMA symbols, i.e. M LBs being UL time transmission units.

If the phases of the correlations between sequences in LBs from UEs within adjacent cells are randomized while the circular auto-correlation and cross-correlation properties of the ZC sequence are maintained, the phase of interference between the adjacent cells is randomized across the LBs during accumulation of the LBs carrying the control information for a subframe at a receiver, thus decreasing an average interference power.

In accordance with an embodiment of the present invention, each UE generates its ZC sequence on an LB basis in a subframe and applies a random sequence having a random phase or a random cyclic shift value to the ZC sequence in each LB, thereby randomizing the ZC sequence. Then the UE transmits control information by the randomized ZC sequence. The random sequence is cell-specific. The interference randomization is further increased using a different random sequence of phase values or cyclic shift values for each UE.

The embodiments of present invention propose three methods. In the following description, a ZC sequence of length N is denoted by g_(p)(n). The ZC sequence g_(p)(n) is randomized over M LBs and control information is multiplied by the randomized ZC sequence g′_(p,m,k)(n) where k denotes the index of a channel carrying the control information.

Equation (2) describes the randomized ZC sequence according to Method 1.

g′ _(p,m,k)(n)=g _(p)((n+d _(k))mod N)·S _(M,m),   (2)

-   -   (m=1,2, . . . , M, n=0,1,2, . . . N−1)         where d_(k) denotes a cyclic shift value of the same ZC         sequence, by which channel k carrying the control information is         identified. The cyclic shift value is preferably a time-domain         cyclic shift value although it can be a frequency-domain cyclic         shift value. In equation (2), mod represents modulo operation.         For instance, A mod B represents the remainder of dividing A by         B.

S_(M,m) denotes an orthogonal code of length M, being +1s or −1s. This orthogonal code can be a Walsh code. m denotes the index of an LB to which the control information is mapped. If the control information is repeated four times in the slots of a subframe, the chips of a Walsh sequence of length 4 are multiplied one to one by the LBs of each slot, and a combination of Walsh sequences for two slots in the subframe is different for each cell, thus randomizing inter-cell interference. For additional randomization, a different combination of Walsh sequences can be used for each UE.

Equation (3) describes the randomized ZC sequence according to Method 2.

g′ _(p,m,k)(n)=g _(p)((n+d _(k))mod N)·e ^(jφm),   (3)

-   -   (m=1,2, . . . , M, n=0,1,2, . . . , N−1)         where φ_(m) denotes a random phase value that changes the phase         of the ZC sequence g_(p)(n) in each LB. Inter-cell interference         is randomized by using different sets of random phase values,         i.e. different random phase sequences {φ_(m)} for adjacent cells         in LBs of a subframe.

Equation (4) describes the randomized ZC sequence according to Method 3.

g′ _(p,m,k)(n)=g _(p)((n+d _(k)+Δ_(m))mod N),   (4)

-   -   (m=1,2, . . . , M, n=0,1.2, . . . , N−1)         where Δ_(m) denotes a random cyclic shift value that changes the         time-domain cyclic shift value d_(k) of the ZC sequence g_(p)(n)         in each LB. Inter-cell interference is randomized by using         different sets of random time-domain cyclic shift values, i.e.         different random time-domain cyclic shift sequences {Δ_(m)} for         adjacent cells in LBs of in a subframe. While the random cyclic         shift values are used in the time domain herein, they can be         adapted to be used in the frequency domain.

FIG. 3 is a flowchart illustrating an operation for transmitting control information using a randomized ZC sequence according to an embodiment of the present invention.

Referring to FIG. 3, a UE receives sequence information and random sequence information from a Node B by signaling in step 302. The sequence information is about a ZC sequence for use in transmitting control information, including the index of the ZC sequence and a cyclic shift value. The random sequence information is used for randomizing the ZC sequence, including a random phase sequence being a set of random phase values or a random time-domain cyclic shift sequence being a set of random time-domain cyclic shift values, for application to LBs of a subframe. The signaling is upper-layer (e.g. L2) signaling or physical layer (L1) signaling. To randomize inter-cell interference, the random phase sequence or the random time-domain cyclic shift sequence is different for each cell. For further interference randomization, the random phase sequence or the random time-domain cyclic shift sequence can also be set to be different for each UE.

In step 304, the UE generates control information and generates complex-valued modulation symbols (hereinafter, referred to as control symbols) using the control information. The number of the control symbols is equal to that of LBs allocated for transmission of the control information. For example, if the control information is 1 bit, the UE creates as many control symbols as the number of the allocated LBs by repetition.

In step 306, the UE generates the ZC sequence using the index and the cyclic shift value included in the sequence information. The UE then generates random values according to the random phase sequence or the random time-domain cyclic shift sequence included in the random sequence information in step 308. The random values are a Walsh sequence, random phase values, or random time-domain cyclic shift values. These random values are different for each cell and/or each UE. The UE generates a randomized ZC sequence by applying the random values to the ZC sequence on an LB basis in step 310. In step 312, the UE multiplies the randomized ZC sequence by the control symbols, maps the products to the LBs, and transmits the mapped LBs.

FIG. 4 is a flowchart illustrating an operation for receiving control information in the Node B according to an embodiment of the present invention.

Referring to FIG. 4, the Node B acquires a correlation signal by correlating a signal received from an intended UE in a plurality of LBs with a ZC sequence applied to the signal in step 402. In step 404, the Node B performs channel estimation on a pilot signal received from the UE and performs channel compensation for the correlation signal using the channel estimate. The Node B acquires control information by applying random values corresponding to the UE to the channel-compensated correlation signal on an LB basis and thus removing random values from the channel-compensated correlation signal in step 406. The random values corresponding to the UE are known from random sequence information that the Node B transmitted to the UE.

In the above transmission and reception of control information, an LB (i.e. an SC-FDMA symbol) is a basic unit to which the control information is mapped for transmission. The ZC sequence is repeated in units of LBs and the elements of the random phase sequence or the random time-domain cyclic shift sequence change LB by LB.

In the case where a plurality of cells exist under the same Node B, UEs within each cell multiplex their control channels using the same ZC sequence and different time-domain cyclic shift values. If different random phase sequences or random time-domain cyclic shift sequences are used on an LB basis in the cells of the Node B, orthogonality may be lost among UEs. Under this environment, therefore, a random phase sequence or a random time-domain cyclic shift sequence is specific to the Node B and the cells of the Node B use the same random sequence.

A first embodiment of the present invention implements Method 1 described in equation (2).

FIG. 5 illustrates a transmission mechanism for control information according to the first embodiment of the present invention.

Referring to FIG. 5, the same 1-bit control information occurs 8 times in one subframe and is subject to frequency hopping on a slot basis in order to achieve frequency diversity. If two SBs and the first and last LBs carry pilots for channel estimation in each slot, the remaining LBs of the slot can be used for transmitting the control information. While one RU is used for transmitting the control information herein, a plurality of RUs can be used to support a plurality of users.

In a first slot, modulation symbols carrying the 1-bit control information occur four times, for transmission in four LBs and are multiplied by an orthogonal code of length 4, S1 502 (=S1 _(4.1) S1 ^(4.2) S1 _(4.3) S1 _(4.4)) on an LB basis. S1 _(4.x) represents chip x of the orthogonal code S1. The pilot sequence is also multiplied by an orthogonal code of length 4, S1′ 504 (=S1′_(4.1) S1′_(4.2) S1′_(4.3) S1′_(4.4)) on an LB or SB basis. The use of orthogonal codes can increase the number of multiple-access users. For example, for length 4, four orthogonal codes are available. The use of the four orthogonal codes enable four times more users to be accommodated in the same time-frequency resources, as compared to non-use of orthogonal codes.

In a second slot, the 1-bit control information occur four times and is multiplied by an orthogonal code of length 4, S2 506 (=S2 _(4.1) S2 _(4.2) S2 _(4.3) S2 _(4.4)) on an LB basis. The pilot sequence is also multiplied by an orthogonal code of length 4, S2′ 508 (=S2′_(4.1) S2′_(4.2) S2′_(4.3) S2′_(4.4)) on an LB or SB basis.

The Node B signals the orthogonal codes S1 502, S1′ 504, S2 506, and S2′ 508 to the UE. Due to the nature of the orthogonal codes, their lengths should be multiples of 4. In FIG. 5, orthogonal codes of length 4 are applied to each slot. If frequency hopping does not take place on a slot basis in the transmission mechanism of FIG. 5, it can be considered that the control information experiences a negligibly small channel change in frequency during one-subframe transmission. Therefore, orthogonality is still maintained even though the length of the orthogonal codes is extended to one subframe. In this case, orthogonal codes of length 8 can be used for transmitting the control information in one subframe.

A different combination of orthogonal codes to be applied to the slots of one subframe is set for each cell to randomize inter-cell interference. For example, for transmitting control information in the slots, Cell A uses orthogonal codes {S1,S2} sequentially and Cell B uses orthogonal codes {S3,S4} sequentially. The orthogonal code combination {S3,S4} includes at least one different orthogonal code from the orthogonal code combination {S1,S2}.

FIGS. 6A and 6B are block diagrams illustrating a transmitter in the UE according to an exemplary embodiment of the present invention.

Referring to FIG. 6A, the transmitter includes a controller 610, a pilot generator 612, a control channel signal generator 614, a data generator 616, a Multiplexer (MUX) 617, a Serial-to-Parallel (S/P) converter 618, a Fast Fourier Transform (FFT) processor 619, a mapper 620, an Inverse Fast Fourier Transform (IFFT) 622, a Parallel-to-Serial (P/S) converter 624, an orthogonal code generator 626, a multiplier 628, a Cyclic Prefix (CP) adder 630, and an antenna 632. Components and an operation related to UL data transmission will not be described herein.

The controller 610 provides overall control to the operation of the transmitter and generates control signals required for the MUX 617, the FFT processor 619, the mapper 620, the pilot generator 612, the control channel signal generator 614, the data generator 616, and the orthogonal code generator 626. The control signal provided to the pilot generator 612 indicates a sequence index and a time-domain cyclic shift value by which to generate a pilot sequence. Control signals associated with UL control information and data transmission are provided to the control channel signal generator 614 and the data generator 616.

The MUX 617 multiplexes a pilot signal, a data signal, and a control channel signal received from the pilot generator 612, the data generator 616, and the control channel signal generator 614 according to timing information indicated by a control signal received from the controller 610, for transmission in an LB or an SB. The mapper 620 maps the multiplexed signal to frequency resources according to LB/SB timing information and frequency allocation information received from the controller 610.

When only control information is transmitted without data, the orthogonal code generator 626 generates orthogonal codes for LBs/SBs according to information about cell-specific or UE-specific orthogonal codes to be used for slots, received from the controller 610, and applies the chips of the orthogonal codes to the control symbols of the control channel signal mapped to LBs according to timing information received from the controller 610. The orthogonal code information is provided to the controller 610 by Node B signaling.

The S/P converter 618 converts the multiplexed signal from the MUX 617 to parallel signals and provides them to the FFT processor 619. The input/output size of the FFT processor 619 varies according to a control signal received from the controller 610. The mapper 620 maps FFT signals from the FFT processor 619 to frequency resources. The IFFT processor 622 converts the mapped frequency signals to time signals and the P/S converter 624 serializes the time signals. The multiplier 628 multiplies the serial time signal by the orthogonal codes generated from the orthogonal code generator 626. That is, the orthogonal code generator 626 generates orthogonal codes to be applied to the slots of a subframe that will carry the control information according to the timing information received from the controller 610.

The CP adder 630 adds a CP to the signal received from the multiplier 628 to avoid inter-symbol interference and transmits the CP-added signal through the transmit antenna 632.

FIG. 6B is a detailed block diagram illustrating the control channel signal generator 614 according to an embodiment of the present invention.

Referring to FIG. 6B, a sequence generator 642 of the control channel signal generator 614 generates a code sequence, for example, a ZC sequence on an LB basis. To do so, the sequence generator 642 receives sequence information such as a sequence length and a sequence index from the controller 610. The sequence information is known to both the Node B and the UE.

A control information generator 640 generates a modulation symbol having 1-bit control information, and a repeater 643 repeats the control symbol to produce as many control symbols as the number of LBs allocated to the control information. A multiplier 646 CDM-multiplexes the control symbols by multiplying the control symbols by the ZC sequence on an LB basis, thus producing a control channel signal.

The multiplier 646 functions to generate the user-multiplexed control channel signal by multiplying the symbols output from the repeater 643 by the ZC sequence. A modified embodiment of the present invention can be contemplated by replacing the multiplier 646 with an equivalent device.

FIGS. 7A and 7B are block diagrams illustrating a receiver in the Node B according to an embodiment of the present invention.

Referring to FIG. 7A, the receiver includes an antenna 710, a CP remover 712, an S/P converter 714, an FFT processor 716, a demapper 718, an IFFT processor 720, a P/S converter 722, a Demultiplexer (DEMUX) 724, a controller 726, a control channel signal receiver 728, a channel estimator 730, and a data demodulator and decoder 732. Components and an operation associated with UL data reception will not be described herein.

The controller 726 provides overall control to the operation of the receiver, and generates control signals required for the DEMUX 724, the IFFT processor 720, the demapper 718, the control channel signal receiver 728, the channel estimator 730, and the data demodulator and decoder 732. Control signals related to UL control information and data are provided to the control channel signal receiver 728 and the data demodulator and decoder 732. A control channel signal indicating a sequence index and a time-domain cyclic shift value is provided to the channel estimator 730. The sequence index and the time-domain cyclic shift value are used to generate a pilot sequence allocated to the UE.

The DEMUX 724 demultiplexes a signal received from the P/S converter 722 into a control channel signal, a data signal, and a pilot signal according to timing information received from the controller 726. The demapper 718 extracts those signals from frequency resources according to LB/SB timing information and frequency allocation information received from the controller 726.

Upon receipt of a signal including control information from the UE through the antenna 710, the CP remover 712 removes a CP from the received signal. The S/P converter 714 converts the CP-free signal to parallel signals and the FFT processor 716 processes the parallel signals by FFT. After demapping in the demapper 718, the FFT signals are converted to time signals in the IFFT processor 720. The input/output size of the IFFT processor 720 varies according to a control signal received form the controller 726. The P/S converter 722 serializes the IFFT signals and the DEMUX 724 demultiplexes the serial signal into the control channel signal, the pilot signal, and the data signal.

The channel estimator 730 acquires a channel estimate from the pilot signal received from the DEMUX 724. The control channel signal receiver 728 channel-compensates the control channel signal received from the DEMUX 724 by the channel estimate and acquires control information transmitted by the UE. The data demodulator and decoder 732 channel-compensates the data signal received from the DEMUX 724 by the channel estimate and then acquires data transmitted by the UE based on the control information.

When only control information is transmitted without data on the UL, the control channel signal receiver 728 acquires the control information in the manner described with reference to FIG. 5.

FIG. 7B is a detailed block diagram illustrating the control channel signal receiver 728 according to an embodiment of the present invention.

Referring to FIG. 7B, the control channel signal receiver 728 includes a correlator 740 and a derandomizer 742. A sequence generator 744 of the correlator 740 generates a code sequence, for example, a ZC sequence used for the UE to generate 1-bit control information. To do so, the sequence generator 744 receives sequence information indicating a sequence length and a sequence index from the controller 726. The sequence information is known to both the Node B and the UE.

A conjugator 746 calculates the conjugate consequence of the ZC sequence. A multiplier 748 CDM-demultiplexes the control channel signal received from the DEMUX 724 by multiplying the control channel signal by the conjugate sequence on an LB basis. An accumulator 750 accumulates the signal received from the multiplier 748 for the length of the ZC sequence. A channel compensator 752 channel-compensates the accumulated signal by the channel estimate received from the channel estimator 730.

In the derandomizer 742, an orthogonal code generator 754 generates orthogonal codes by which the UE uses in transmitting the 1-bit control information, according to orthogonal code information. A multiplier 758 multiplies the channel-compensated signal by the chips of the orthogonal sequences on an LB basis. An accumulator 760 accumulates the signal received from the multiplier 758 for the number of LBs to which the 1-bit control information was repeatedly mapped, thereby acquiring the 1-bit control information. The orthogonal code information is signaled from the Node B to the UE so that both the Node B and the UE are aware of the orthogonal code information.

In a modified embodiment of the present invention, channel compensator 752 is disposed between multiplier 758 and accumulator 760. While correlator 740 and derandomizer 742 are separately configured in FIG. 7B, sequence generator 744 of correlator 740 and orthogonal code generator 754 of derandomizer 742 can be incorporated into a single device depending on a configuration method. For example, if correlator 740 is configured so that sequence generator 744 generates a ZC sequence with an orthogonal code applied on an LB basis for each UE, multiplier 758 and orthogonal code generator 754 of derandomizer 742 are not used. Thus, a device equivalent to that illustrated in FIG. 7B is achieved.

A second embodiment of the present invention implements Method 2 described in equation (3).

FIG. 8 is a diagram illustrating a transmission mechanism for control information according to an embodiment of the present invention.

Referring to FIG. 8, one slot includes a total of 7 LBs, and the fourth LB carries a pilot signal in each slot. Hence, one subframe has 14 LBs in total, and 2 LBs are used for pilot transmission and 12 LBs for control information transmission. While one RU is used for transmitting control information herein, a plurality of RUs can be used to support a plurality of users.

The same 1-bit control information occurs 6 times in each slot, thus 12 times in one subframe. For frequency diversity, frequency hopping is performed for the control information on a slot basis. A random phase is applied to a ZC sequence in each LB carrying the control information. The resulting randomization of the ZC sequence randomizes inter-cell interference.

Random phase values applied to the ZC sequence in LBs are φ₁,φ₂, . . . , φ₁₂ 802 to 824. The ZC sequence is multiplied by e^(jφm)(m=1, 2, . . . , 12), thus being phase-rotated. As a random phase sequence being a set of random phase values for LBs is cell-specific, the inter-cell interference is randomized. That is, since the correlation between randomized ZC sequences used for LBs of different cells is randomly phase-rotated over one subframe, interference between control channels from the cells is reduced.

The Node B signals the random phase sequence to the UE so that both are aware of the random phase sequence. To reduce the inter-cell interference, a cell-specific random phase value can also be applied to the pilot signal. The Node B signals the random phase value to the UE so that both are aware of the random phase sequence.

FIG. 9 is a diagram illustrating another transmission mechanism for control information according to an embodiment of the present invention.

Referring to FIG. 9, one slot includes a total of 6 LBs and 2 SBs carrying a pilot signal. Hence, one subframe has 12 LBs in total, and 4 LBs are used for pilot transmission and 12 LBs for control information transmission. The same 1-bit control information occurs 6 times in each slot, thus 12 times in one subframe. For frequency diversity, frequency hopping is performed for the control information on a slot basis. Random phase values applied to the ZC sequence in LBs are φ₁,φ₂, . . . , φ₁₂ 902 to 924.

FIGS. 10A and 10B are block diagrams illustrating a transmitter in the UE according to an embodiment of the present invention.

Referring to FIG. 10A, the transmitter includes a controller 1010, a pilot generator 1012, a control channel signal generator 1014, a data generator 1016, a MUX 1017, an S/P converter 1018, an FFT processor 1019, a mapper 1020, an IFFT 1022, a P/S converter 1024, a CP adder 1030, and an antenna 1032. Components and an operation related to UL data transmission will not be described herein.

The controller 1010 provides overall control to the operation of the transmitter and generates control signals required for the MUX 1017, the FFT processor 1019, the mapper 1020, the pilot generator 1012, the control channel signal generator 1014, and the data generator 1016. A control signal provided to the pilot generator 1012 indicates a sequence index indicating an allocated pilot sequence and a time-domain cyclic shift value, for pilot generation. Control signals associated with UL control information and data transmission are provided to the control channel signal generator 1014 and the data generator 1016.

The MUX 1017 multiplexes a pilot signal, a data signal, and a control channel signal received from the pilot generator 1012, the data generator 1016, and the control channel signal generator 1014 according to timing information indicated by a control signal received from the controller 1010, for transmission in an LB or an SB. The mapper 1020 maps the multiplexed information to frequency resources according to LB/SB timing information and frequency allocation information received from the controller 1010.

When only control information is transmitted without data, the control channel signal generator 1014 generates a control channel signal by applying a ZC sequence randomized on an LB basis to control information in the afore-described method.

The S/P converter 1018 converts the multiplexed signal from the MUX 1017 to parallel signals and provides them to the FFT processor 1019. The input/output size of the FFT processor 1019 varies according to a control signal received from the controller 1010. The mapper 1020 maps FFT signals from the FFT processor 1019 to frequency resources. The IFFT processor 1022 converts the mapped frequency signals to time signals and the P/S converter 1024 serializes the time signals. The CP adder 1030 adds a CP to the serial signal and transmits the CP-added signal through the transmit antenna 1032.

FIG. 10B is a detailed block diagram illustrating the control channel signal generator 1014 according to an embodiment of the present invention.

Referring to FIG. 10B, a sequence generator 1042 of the control channel signal generator 1014 generates a code sequence, for example, a ZC sequence to be used for LBs. A randomizer 1044 generates a random phase value for each LB and multiplies the random phase value by the ZC sequence in each LB. To do so, the sequence generator 1042 receives sequence information such as a sequence length and a sequence index from the controller 1010 and the randomizer 1044 receives random sequence information about the random phase value for each LB from the controller 1010. Then, the randomizer 1044 rotates the phase of the ZC sequence by the random phase value in each LB, thus randomizing the phase of the ZC sequence. The sequence information and the random sequence information are known to both the Node B and the UE.

A control information generator 1040 generates a modulation symbol having 1-bit control information and a repeater 1043 repeats the control symbol to produce as many control symbols as the number of LBs allocated to the control information. A multiplier 1046 CDM-multiplexes the control symbols by multiplying the control symbols by the randomized ZC sequence on an LB basis, thus producing a control channel signal.

The multiplier 1046 functions to randomize the symbols output from the repeater 1043 by the randomized ZC sequence on a symbol basis. A modified embodiment of the present invention can be contemplated by replacing the multiplier 1046 with a device that performs a function equivalent to applying or combining the randomized ZC sequence to or with the control symbols. For example, multiplier 1046 can be replaced with a phase rotator that changes the phases of the control symbols according to the phase values of the randomized ZC sequence, φ_(m) or Δ_(m).

FIGS. 11A and 11B are block diagrams illustrating a receiver in the Node B according to an embodiment of the present invention.

Referring to FIG 11A, the receiver includes an antenna 1110, a CP remover 1112, an S/P converter 1114, an FFT processor 1116, a demapper 1118, an IFFT processor 1120, a P/S converter 1122, a DEMUX 1124, a controller 1126, a control channel signal receiver 1128, a channel estimator 1130, and a data demodulator and decoder 1132. Components and an operation associated with UL data reception will not be described herein.

The controller 1126 provides overall control to the operation of the receiver. It also generates control signals required for the DEMUX 1124, the IFFT processor 1120, the demapper 1118, the control channel signal receiver 1128, the channel estimator 1130, and the data demodulator and decoder 1132. Control signals related to UL control information and data are provided to the control channel signal receiver 1128 and the data demodulator and decoder 1132. A control signal indicating a sequence index indicating a pilot sequence allocated to the UE and a time-domain cyclic shift value is provided to the channel estimator 1130. The sequence index and the time-domain cyclic shift value are used for pilot reception.

The DEMUX 1124 demultiplexes a signal received from the P/S converter 1122 into a control channel signal, a data signal, and a pilot signal according to timing information received from the controller 1126. The demapper 1118 extracts those signals from frequency resources according to LB/SB timing information and frequency allocation information received from the controller 1126.

Upon receipt of a signal including control information from the UE through the antenna 1110, the CP remover 1112 removes a CP from the received signal. The S/P converter 1114 converts the CP-free signal to parallel signals and the FFT processor 1116 processes the parallel signals by FFT. After processing in the demapper 1118, the FFT signals are converted to time signals in the IFFT processor 1120. The P/S converter 1122 serializes the IFFT signals and the DEMUX 1124 demultiplexes the serial signal into the control channel signal, the pilot signal, and the data signal.

The channel estimator 1130 acquires a channel estimate from the pilot signal received from the DEMUX 1124. The control channel signal receiver 1128 channel-compensates the control channel signal received from the DEMUX 1124 by the channel estimate and acquires the control information transmitted by the UE. The data demodulator and decoder 1132 channel-compensates the data signal received from the DEMUX 1124 by the channel estimate and then acquires data transmitted by the UE based on the control information.

When only control information is transmitted without data on the UL, the control channel signal receiver 1128 acquires the control information in the manner described with reference to FIGS. 8 and 9.

FIG. 11B is a detailed block diagram illustrating the control channel signal receiver 1128 according to an embodiment of the present invention.

Referring to FIG. 11B, the control channel signal receiver 1128 includes a correlator 1140 and a derandomizer 1142. A sequence generator 1144 of the correlator 1140 generates a code sequence, for example, a ZC sequence used for the UE to generate control information. To do so, the sequence generator 1144 receives sequence information indicating a sequence length and a sequence index from the controller 1126. The sequence information is known to both the Node B and the UE.

A conjugator 1146 calculates the conjugate consequence of the ZC sequence. A multiplier 1148 CDM-demultiplexes the control channel signal received from the DEMUX 1124 by multiplying the control channel signal by the conjugate sequence on an LB basis. An accumulator 1150 accumulates the product signal for the length of the ZC sequence. The multiplier 1148 of the correlator 1140 can be replaced with a phase rotator that changes the phases of the control channel signal on an LB basis according to the phase values d_(k) of the sequence received from sequence generator 1144. A channel compensator 1152 channel-compensates the accumulated signal by the channel estimate received from the channel estimator 1130.

In the derandomizer 1142, a random value generator 1156 calculates the conjugate phase values of random phase values that the UE uses in transmitting the control information, according to random sequence information. A multiplier 1158 multiplies the channel-compensated signal by the conjugate phase values on an LB basis. Like The multiplier 1046 of the transmitter, the multiplier 1158 of the derandomizer 1142 can be replaced with a phase rotator that changes the phases of the control channel signal on an LB basis according to the phase values φ_(m) or Δ_(m) of the random sequence received from the sequence generator 1156.

An accumulator 1160 accumulates the signal received from the multiplier 1158 for the number of LBs to which the 1-bit control information was repeatedly mapped, thereby acquiring the 1-bit control information. The random sequence information is signaled from the Node B to the UE so that both are aware of the random sequence information.

In a modified embodiment of the present invention, the channel compensator 1152 is disposed between the multiplier 1158 and the accumulator 1160. While the correlator 1140 and the derandomizer 1142 are separately configured in FIG. 11B, the sequence generator 1144 of the correlator 1140 and the random value generator 1156 of the derandomizer 1142 can be incorporated into a single device depending on a configuration method. For example, if the correlator 1140 is configured so that the sequence generator 1144 generates a ZC sequence to which a random sequence is applied for each UE, the multiplier 1158 and the random value generator 1156 of the derandomizer 1142 are not used. Thus, a device equivalent to that illustrated in FIG. 11B is achieved. In this case, like the multiplier 1046 of the transmitter, the multiplier 1148 of the correlator 1140 can be replaced with a phase rotator that changes the phases of the control channel signal on a symbol basis according to the phase values (d_(k)+φ_(m)) or (d_(k)+Δ_(m)) of the sequence received from the sequence generator 1144.

The inter-cell interference randomization can be further increased by setting a different phase value for each LB to each UE. The Node B signals the phase value of each LB to each UE.

Aside from a random sequence as a phase sequence applied to 12 LBs carrying 1-bit control information, an orthogonal phase sequence such as a Fourier sequence can be used in the second exemplary embodiment of the present invention. A Fourier sequence of length N is defined as

$\begin{matrix} {{{f_{k}(n)} = ^{{- j}\frac{2\pi \; {kn}}{N}}},\left( {{n = 0},\ldots \mspace{11mu},{N - 1},{k = 0},\ldots \mspace{11mu},{N - 1}} \right)} & (5) \end{matrix}$

In equation (5), a different cell-specific value k is set for each cell. When phase rotation is performed on an LB basis using a different Fourier sequence for each cell, there is no interference among cells if timing is synchronized among the cells.

The first and second exemplary embodiments can be implemented in combination. In the transmission mechanism of FIG. 5, LBs carrying 1-bit control information are multiplied by an orthogonal code and then by a random phase sequence. As the random phase sequence is cell-specific, the inter-cell interference is reduced.

A third embodiment of the present invention implements Method 3 described in equation (4).

The time-domain cyclic shift value of a ZC sequence is cell-specific and changes in each LB that carries control information, thereby randomizing inter-cell interference. To be more specific, a cell-specific cyclic shift value Δ_(m) applied to each LB is further applied in the time domain in addition to a cyclic shift value d_(k) applied to each of control channels that are CDM-multiplexed in the same frequency resources within a cell. The Node B signals the cell-specific cyclic shift value to the UE. The cell-specific cyclic shift value is set to be larger than the maximum delay of a radio transmission path in order to keep the orthogonality of the ZC sequence.

To reduce the inter-cell interference, a cell-specific random time-domain cyclic shift value can also be applied to the pilot signal. The Node B signals the random time-domain cyclic shift value to the UE so that the random time-domain cyclic shift sequence is known to both the Node B and the UE.

FIG. 12A is a diagram illustrating a transmission mechanism for control information according to an embodiment of the present invention.

Referring to FIG. 12A, one slot includes a total of 7 LBs and the fourth LB carries a pilot signal in each slot. Hence, one subframe has 14 LBs in total, and 2 LBs are used for pilot transmission and 12 LBs for control information transmission. While one RU is used for transmitting control information herein, a plurality of RUs can be used to support a plurality of users.

Random time-domain cyclic shift values applied to the 12 LBs of the ZC sequenceare Δ₁,Δ₂, . . . , Δ₁₂ 1202 to 1224. The ZC sequence is cyclically shifted by the random time-domain cyclic shift values 1202 to 1224 on an LB basis to randomize the control information.

FIG. 12B is a detailed view of FIG. 12A. To CDM-multiplex different control channels within a cell, the same time-domain cyclic shift value d_(k) (k is a control channel index) applies to each LB, and to randomize interference between control information from adjacent cells, different cell-specific time-domain cyclic shift values 1202 to 1224 apply to LBs. That is, the ZC sequence is additionally cyclically shifted by a time-domain cyclic shift value for each UE in the cell. Reference numerals 1230 and 1232 denote first and second slots, respectively in one subframe. For convenience sake, frequency hopping is not shown.

When a UE-specific time-domain cyclic shift is used for additional randomization, the time-domain cyclic shift values 1202 to 1224 indicate a UE-specific random sequence and the combination of d_(k) and the time-domain cyclic shift values 1202 to 1224 maintains orthogonality among the control channels within the same cell.

FIG. 13 is a diagram illustrating another transmission mechanism for control information according an embodiment of the present invention. Time-domain cyclic shift values of a ZC sequence for 12 LBs are Δ₁,Δ₂, . . . , Δ₁₂ 1302 and 1324. The ZC sequence is cyclically shifted in each LB by a time-domain cyclic shift value in order to randomize control information.

A transmitter and a receiver according to the third exemplary embodiment of the present invention are identical in configuration to those illustrated in FIGS. 10A and 10B and FIGS. 11A and 11B, except that the randomizer 1044 illustrated in FIG. 10B randomizes a ZC sequence with random time-domain cyclic shifts on an LB basis, and S the random value generator 1156 illustrated in FIG. 11B calculates the conjugate phase value of the random time-domain cyclic shift value of each LB and provides it to the multiplier 1158.

The first and third embodiments can be implemented in combination. That is, in the transmission mechanism of FIG. 5, control information is multiplied by an orthogonal code, and then additionally by a random cyclic shift sequence on an LB basis as illustrated in FIG. 12 or FIG. 13. As the random cyclic shift sequence is different for each cell, the inter-cell interference is reduced.

As is apparent from the above description, the present invention advantageously reduces inter-cell interference by applying a random phase or a cyclic shift value to each block on a cell basis or on a UE basis, when UL control information from different users is multiplexed in a future-generation multi-cell mobile communication system.

While the invention has been shown and described with reference to certain preferred embodiments thereof, they are mere preferred applications. For example, the embodiments of the present invention are applicable to control information with a plurality of bits, such as a CQI, as well as 1-bit control information. Also, a random value for a code sequence used for control information can be applied in a predetermined resource block basis as well as on an LB basis. Thus, it will be understood by those skilled in the art that various changes in form and details may be made therein without departing from the spirit and scope of the present invention as defined by the appended claims. 

1. A method for transmitting control information in a Single Carrier-Frequency Division Multiple Access (SC-FDMA) system, comprising the steps of: generating different orthogonal codes for different slots, each comprising a plurality of SC-FDMA symbols in a subframe; generating a control channel signal by multiplying control symbols carrying control information by a sequence allocated for Code Division Multiplexing (CDM) of the control information; and multiplying the control channel signal by chips of the orthogonal codes on an SC-FDMA symbol basis, and transmitting the multiplied control channel signal in the SC-FDMA symbols.
 2. The method of claim 1, wherein a combination of the orthogonal codes used in the subframe is different for each cell.
 3. The method of claim 1, wherein a combination of the orthogonal codes used in the subframe is different for at least one of each cell and each User Equipment (UE), and signaled from a Node B to a UE.
 4. The method of claim 1, wherein the sequence is a cell-specific Zadoff-Chu (ZC) sequence.
 5. The method of claim 1, wherein the multiplication and transmission comprises multiplying as many control symbols carrying the control information as the number of the SC-FDMA symbols by the randomized sequences and transmitting the multiplied control symbols.
 6. A method for receiving control information in a Single Carrier-Frequency Division Multiple Access (SC-FDMA) system, comprising the steps of: generating different orthogonal codes for different slots each comprising a plurality of SC-FDMA symbols in a subframe; multiplying a received control channel signal by a conjugate sequence of a sequence allocated for Code Division Multiplexing (CDM) of the control information; and acquiring the control information by multiplying the multiplied control channel signal by chips of the orthogonal codes on an SC-FDMA symbol basis.
 7. The method of claim 6, wherein a combination of the orthogonal codes used in the subframe is different for each cell.
 8. The method of claim 6, wherein a combination of the orthogonal codes used in the subframe is different for at least one of each cell and each User Equipment (UE), and signaled from a Node B to a UE.
 9. The method of claim 6, wherein the sequence is a cell-specific Zadoff-Chu (ZC) sequence.
 10. The method of claim 6, wherein the acquisition comprises multiplying as many control symbols forming the control channel signal as the number of the SC-FDMA symbols by the conjugate sequence.
 11. An apparatus for transmitting control information in a Single Carrier-Frequency Division Multiple Access (SC-FDMA) system, comprising: a control channel signal generator for generating a control channel signal by multiplying control symbols comprising control information by a sequence allocated for Code Division Multiplexing (CDM) of the control information; and a transmitter for generating different orthogonal codes for different slots each comprising a plurality of SC-FDMA symbols in a subframe, multiplying the control channel signal by chips of the orthogonal codes on an SC-FDMA symbol basis, and transmitting the multiplied control channel signal in the SC-FDMA symbols.
 12. The apparatus of claim 11, wherein a combination of the orthogonal codes used in the subframe is different for each cell.
 13. The apparatus of claim 11, wherein a combination of the orthogonal codes used in the subframe is different for at least one of each cell and each User Equipment (UE), and signaled from a Node B to a UE.
 14. The apparatus of claim 11, wherein the sequence is a cell-specific Zadoff-Chu (ZC) sequence.
 15. The apparatus of claim 11, wherein the randomizer multiplies as many control symbols comprising the control information as the number of the SC-FDMA symbols by the randomized sequences and transmitting the multiplied control symbols.
 16. An apparatus for receiving control information in a Single Carrier-Frequency Division Multiple Access (SC-FDMA) system, comprising: a receiver for receiving a control channel signal comprising control information; and a control channel signal receiver for multiplying the control channel signal by a conjugate sequence of a sequence allocated for Code Division Multiplexing (CDM) of the control information and acquiring the control information by multiplying the multiplied control channel signal by chips of different orthogonal codes used for different slots each comprising a plurality of SC-FDMA symbols in a subframe, on an SC-FDMA symbol basis.
 17. The apparatus of claim 16, wherein a combination of the orthogonal codes used in the subframe is different for each cell.
 18. The apparatus of claim 16, wherein a combination of the orthogonal codes used in the subframe is different for at least one of each cell and each User Equipment (UE), and signaled from a Node B to a UE.
 19. The apparatus of claim 16, wherein the sequence is a cell-specific Zadoff-Chu (ZC) sequence.
 20. The apparatus of claim 16, wherein the control channel signal receiver multiplies as many control symbols forming the control channel signal as the number of the SC-FDMA symbols by the orthogonal codes. 